Multi-Element Assessment of Potentially Toxic and Essential Elements in New and Traditional Food Varieties in Sweden

With the global movement toward the consumption of a more sustainable diet that includes a higher proportion of plant-based foods, it is important to determine how such a change could alter the intake of cadmium and other elements, both essential and toxic. In this study, we report on the levels of a wide range of elements in foodstuffs that are both traditional and “new” to the Swedish market. The data were obtained using analytical methods providing very low detection limits and include market basket data for different food groups to provide the general levels in foods consumed in Sweden and to facilitate comparisons among traditional and “new” food items. This dataset could be used to estimate changes in nutritional intake as well as exposure associated with a change in diet. The concentrations of known toxic and essential elements are provided for all the food matrices studied. Moreover, the concentrations of less routinely analyzed elements are available in some matrices. Depending on the food variety, the dataset includes the concentrations of inorganic arsenic and up to 74 elements (Ag, Al, As, Au, B, Ba, Be, Bi, Ca, Cd, Co, Cr, Cs, Cu, Fe, Ga, Ge, Hf, Hg, K, Li, Mg, Mn, Mo, Na, Nb, Ni, P, Pb, Rb, S, Sb, Sc, Se, Si, Sn, Sr, Ta, Te, Th, Ti, Tl, U, W, V, Y, Zn, Zr, rare Earth elements (REEs) (Ce, Dy, Er, Eu, Gd, Ho, La, Lu, Nd, Pr, Sm, Tb, Tm, and Yb), platinum group elements (PGEs) (Ir, Os, Pd, Pr, Pt, Re, Rh, Ru, and Pr), and halogens (Br, Cl, and I)). The main focus (and thus the most detailed information on variation within a given food group) is on foods that are currently the largest contributors to dietary cadmium exposure in Sweden, such as pasta, rice, potato products, and different sorts of bread. Additionally, elemental concentrations in selected food varieties regarded as relatively new or “novel” to the Swedish market are provided, including teff flour, chia seeds, algae products, and gluten-free products.


Introduction
Cadmium (Cd), lead (Pb), mercury (Hg), and arsenic (As) are well known for their toxicity. They are on the World Health Organization (WHO)'s list of the top 10 chemicals of major health concern [1]. These four elements are commonly referred to as "heavy metals," even though arsenic is a metalloid. Their presence in food, both of natural and anthropogenic origin, has caused concern within the European Food Safety Authority (EFSA) [2][3][4][5]. In addition, there has been increasing interest in the occurrence of silver (Ag) [6], aluminum (Al) [7] (EFSA, 2008), and nickel (Ni) [8,9] caused by the increasing use of Ag as a food preservative agent and Al as a food additive, packing material, and component of drinking water production. Nickel has recently attracted more interest and needs further evaluation according to the EFSA, as it was recently concluded that it may pose a health risk, especially for younger age groups, that is not limited to nickel-sensitive individuals [9]. Due to the drive to increase the share of plant-based foods and foods of marine origins, including algae, in the human diet, the variety of "new" and so-called "novel" foods available on the market has expanded. In the EU, this segment is classified under Regulation (EU) No 2015/2283 [21], which states that food items that were not consumed in the EU in substantial amounts before 1997 are classified as novel foods. For example, the brown algae Sachharina latissima (sugar kelp) was consumed in the EU before 1997 and Due to the drive to increase the share of plant-based foods and foods of marine origins, including algae, in the human diet, the variety of "new" and so-called "novel" foods available on the market has expanded. In the EU, this segment is classified under Regulation (EU) No 2015/2283 [21], which states that food items that were not consumed in the EU in substantial amounts before 1997 are classified as novel foods. For example, the brown algae Sachharina latissima (sugar kelp) was consumed in the EU before 1997 and thus is not classified as a novel food. Although knowledge of the elemental composition of new and novel foods is crucial for providing scientifically based recommendations for maintaining a healthy diet, for obvious reasons, information on the elemental composition of novel food is scarcer compared to traditional foods. This is also the case for foods that are not classified as novel but are still "new" to the average consumer.
In response to the concerns of the EFSA and its call for data, especially regarding Cd [2,22], since 2014, the Swedish Food Agency has facilitated data collection on Cd and other elements by analyzing around 100 individual food items yearly. These are mainly traditional foods that contribute significantly to cadmium intake in the Swedish diet, but foods that are newer to the market are also included.
The aim of this study was to improve knowledge of levels of Cd and other elements within and between individual food items. We also considered concentrations below the current MLs. Our focus was on the food categories that contribute the most to the exposure to Cd in Sweden and those that are readily/broadly available for regular consumers, including both Swedish-produced and imported foods. The data include information on levels of known toxic (As, Cd, Pb, Hg) and essential (Mo, Fe, Cu, Zn, Se, calcium (Ca), magnesium (Mg), etc.) elements, as well as less routinely analyzed elements in food, such as Ni, thallium (Tl), uranium (U), vanadium (V), rare Earth elements (REEs), and platinum group elements (PGEs). For the sake of brevity, only selected results are evaluated and discussed in detail, while the complete dataset is provided to facilitate research by other groups (for example, for estimations of nutrient intake and/or exposure to toxic elements), as well as general discussions on levels of different elements in both traditional and "new" foods.

Reagents and Standards
All calibration and internal standard solutions were prepared by serial dilutions of single-element stocks (1000 and 10,000 mg L −1 , SPEX Plasma Standards, Edison, NJ, USA and Promochem AB, Ulricehamn, Sweden). Analytical grade nitric acid (Merck, Darmstadt, Germany) was used after additional purification by sub-boiling distillation in a quartz still. Analytical grade ethylenediamine tetraacetic acid disodium salt dihydrate (EDTA), Triton-X100 surfactant, hydrochloric acid, and 25% SupraPure grade ammonia solution (all from Merck) were used as supplied. The three-stage water purification procedure consists of ion-exchange (SeraDest), a Milli-Q system (>18 MΩ; Millipore Milli-Q, Bedford, MA, USA) and finally sub-boiling distillation in Teflon stills (Savilex Corp., Minnetonka, MN, USA). Water produced in this fashion was used exclusively for the dilution of samples, blanks, and standards. For other, less critical operations, water from the Milli-Q system was used directly.
Reagents and standards used at the Swedish Food Agency were of analytical quality (p.a.) or better. Calibration standards for total determination were prepared by serial dilutions of multi-element stock (Spectrascan, Teknolab AS, Ski, Norway) or for iAs a singleelement stock was used (Inorganic Ventures, Christiansburg, VA, USA). Analytical-grade nitric and hydrochloric acids (Merck, Darmstadt, Germany) were used after additional purification by sub-boiling distillation in a quartz still. Ultrapure water (Q-POD Element, Merck Millipore, Darmstadt, Germany) was used for preparation of standards and dilution of concentrated acids, and for other purposes water from a Milli-Q system (>18 MΩ; Merck Millipore) was used.

Instrumentation
Food samples were homogenized using either a Retsch Ultra Centrifugal Mill ZM 100 (Retsch, Haan, Germany), which includes a stainless-steel pan and a 4 mm Ti sieve, or a large food processor (Foss Homogenizer 2094, A/S Foss, Hillerød, Denmark) with a stainless pan and stainless knife, for dry samples. For the homogenization of fresh samples, a Braun food processor with a Ti blade (Braun GmbH, Kronberg, Germany) was used. Total digestion was performed by microwave digestion (MARS-5 or MARS-6, CEM Corporation, Matthews, NC, USA) or by graphite hot-block digestion (DHB R3, ALS Global, Vancouver, BC, Canada).
For the determination of halogens, samples were sintered in a calibrated Heraeus KM 170 furnace (Karlsruhe, Germany). A microwave digestion unit (MARS-5, CEM Corporation) equipped with 12 perfluoroalkoxy (PFA)-lined vessels (ACV 125) with safety rupture membranes (maximum operating pressure 1380 kPa) was used for acid digestion.
The determination of total concentrations of elements in the majority of samples was performed by high-resolution inductively coupled plasma mass spectrometry (HR-ICP-MS (ELEMENT XR, Thermo Scientific, Bremen, Germany)) at ALS Scandinavia AB, Luleå, Sweden. Samples of wild Ulva, pumpkin seeds, sunflower seeds, peanuts, and vegetarian protein products were analyzed at Swedish Food Agency, Uppsala, Sweden, using a single quadrupole ICP-MS (Agilent 7700x ICP-MS, Santa Clara, CA, USA). Levels of inorganic arsenic were determined at the Swedish Food Agency by using strong anion exchange HPLC-ICP-MS (high-performance liquid chromatography-inductively coupled plasma mass spectrometry, Agilent 1260 Infinity Quaternary LC (Santa Clara, CA, USA) and Agilent 7700x ICP-MS).

Samples Selection of Samples
According to an earlier market basket study [16], food groups such as cereal products, potato products, and vegetables together contribute around 76% to the exposure to Cd in Sweden. Food items representing these groups were selected with a focus on (1) foods with lesser-known levels of Cd, (2) frequently consumed foods, (3) foods containing several ingredients with different maximum levels, and (4) foods that are "new" to the Swedish market for which consumption is increasing or is predicted to increase. In addition, the simplicity of sample handling (i.e., collection, storage, and sample preparation) was taken into account, as well as the availability of samples from other ongoing projects at the Swedish Food Agency. Table 1 provides information about selected food items together with the sampling year and other projects involving the same samples. The food items were purchased from major grocery chains in Sweden. At least 1 kg, or a minimum of three packages of each product, was collected following the regulations for sampling and analysis for the official control of levels of trace elements and processing contaminants in foodstuffs (Regulation (EC) No 333/2007 [28]. In general, the entire sample (edible parts) was milled to a fine powder/slurry before a subsample was extracted for analysis. Mills and mixers generally included titanium (Ti) parts in order to avoid contamination from stainless steel, i.e., by Fe, Ni, and chromium (Cr). Liquid samples were thoroughly mixed in a beaker before the subsample was extracted. Any exceptions to this general procedure are described below.

Bread
In order to reduce the amount of soft bread, crisp bread, or rice cake that required homogenization to provide a representative sample, one of two homogenization methods was used. Either each slice of bread in the package was halved and homogenized (the other half was discarded), or every second slice of bread was homogenized (the other slice was discarded).

Potatoes
Fresh potatoes were washed and scrubbed with ultrapure water in a similar way to that done prior to household cooking. From the potato packages, each potato was divided in half, and one of the halves was peeled and the other was left unpeeled. The peeled halves and the unpeeled halves were mixed separately to form homogenous slurries, representing two subsamples of each sort of potato purchased. This procedure was used to mimic a regular consumer either peeling the potatoes or not prior to cooking and consumption.

Algae and Algae Products
Algae oil capsules were purchased from health food stores in Uppsala and Stockholm and also from the internet-one package of each. The oil was analyzed separately as two capsules from each product. Algae salad and macroalgae sheets, purchased from local stores, were homogenized in a food processor.
Ulva samples were collected, freeze-dried (homemade device) and milled by mortar and pestle at the Department of Marine Sciences, University of Gothenburg, Sweden. The collection sites were located along the Swedish coast and in the south of Norway, as marked in Figure 2 [25]. Samples of sugar kelp were collected from sea farms in the Koster Archipelago on the west coast of Sweden. All samples of wild and farmed seaweed were freeze-dried and homogenized [26,27].
In order to reduce the amount of soft bread, crisp bread, or rice cake that required homogenization to provide a representative sample, one of two homogenization methods was used. Either each slice of bread in the package was halved and homogenized (the other half was discarded), or every second slice of bread was homogenized (the other slice was discarded).

Potatoes
Fresh potatoes were washed and scrubbed with ultrapure water in a similar way to that done prior to household cooking. From the potato packages, each potato was divided in half, and one of the halves was peeled and the other was left unpeeled. The peeled halves and the unpeeled halves were mixed separately to form homogenous slurries, representing two subsamples of each sort of potato purchased. This procedure was used to mimic a regular consumer either peeling the potatoes or not prior to cooking and consumption.

Algae and Algae Products
Algae oil capsules were purchased from health food stores in Uppsala and Stockholm and also from the internet-one package of each. The oil was analyzed separately as two capsules from each product. Algae salad and macroalgae sheets, purchased from local stores, were homogenized in a food processor.
Ulva samples were collected, freeze-dried (homemade device) and milled by mortar and pestle at the Department of Marine Sciences, University of Gothenburg, Sweden. The collection sites were located along the Swedish coast and in the south of Norway, as marked in Figure 2 [25]. Samples of sugar kelp were collected from sea farms in the Koster Archipelago on the west coast of Sweden. All samples of wild and farmed seaweed were freeze-dried and homogenized [26,27]. The blue dots indicate sites at which Ulva fenestrata was sampled, the yellow dots show sites at which Ulva lacinulata was collected, and the red dots show sites at which Ulva intestinalis was collected [25]. All collected populations were examined molecularly for species identification; for GenBank accession numbers, see Table S1.

Total Element Determination
The determination of total concentrations of elements in the majority of samples was performed by using HR-ICP-MS at ALS Scandinavia AB, Luleå, Sweden. Sample preparation was performed in a Class 10,000 clean laboratory areas by personnel wearing clean room attire. The general precautions detailed by Rodushkin et al. [29] were taken to minimize contamination. In order to achieve the lowest possible detection limits and to avoid the contamination risks associated with the additional homogenization of samples, the sample amount was increased to >1 g per digestion. Weighing was performed directly into 50 mL acid-washed plastic vessels. After the addition of concentrated nitric acid (10:1, v/m), samples were left to react overnight, followed by graphite hot-block digestion (105 • C, 2 h). Though the complete digestion of refractory phases in some matrices may require the addition of HF acid [30], as elements associated with such phases are unlikely to contribute to the nutritional uptake, the use of this acid was omitted. After cooling, the volume of transparent digests was adjusted to 40 mL with MQ water. Prior to the analysis stage, samples were further diluted to provide a total dilution factor of approximately 100 and a nitric acid concentration of 1.4 M. A set of preparation blanks, duplicate samples, and control materials was prepared alongside the samples. For the determination of halogens, samples were prepared using Na 2 CO 3 + ZnO sintering [31].
The concentrations of elements of interest were measured by HR-ICP-MS using a combination of internal standards (indium (In) and lutetium (Lu) when REE was not analyzed) added to all solutions at 1 µg/L and external calibration with set of standards matching the acid strength of sample digests. The all-PFA introduction system, high-sensitivity X-type skimmer cone, and FAST autosampler (excluding the contact of sample digests with peristaltic pump tubing) allow an instrumental sensitivity in excess of 2000 counts/s for 1 ng/L In and background equivalent concentrations for ultra-trace elements (Cd, Pb, As) below 0.2 ng/L. Methane was added to the plasma to decrease the formation of oxidebased spectral interferences, improve the sensitivity of elements with high first-ionization potentials, and minimize matrix effects [32]. Spectral interferences were either avoided by using high-resolution MS settings or mathematical correction was performed (for example, isobaric interferences from tin (Sn) and In, as well as molybdenum oxide interferences on Cd isotopes). Concentrations of halogens were measured in a separate sequence using ethylenediaminetetraacetic acid disodium salt dihydrate, Triton X-100, and an ammonia mixture in order to reduce carry-over in the introduction system and suppress the effect of the oxidation state on the analyte intensity [31]. The method detection limits (defined as 3 times the standard deviation of analyte concentrations measured in a set of preparation blanks) are presented in Table 2. The combined, extended (k = 2) measurement uncertainty was below 15% for Co, Cr, Cu, Fe, I, K, Mn, Mo, Na, P, Se, and Zn and between 10 and 50% for As, Ag, Al, Cd, Hg, Ni, and Pb, depending on the element and its level of concentration. This method is based on the accredited method used by ALS Scandinavia AB in their routine work for the analysis of biological matrices [33,34]. Table 2. Typical limits of detection (LOD, 3 × std for blank, n = 9) with a total dilution factor of 100 for selected elements measured by HR-ICP-MS. Individual LODs for each batch are presented in Tables S2-S10. It should be noted that, because of the numerous unresolved spectral interferences affecting isotopes of some ultra-trace elements (germanium (Ge), osmium (Os), palladium (Pd), rhodium (Rh), ruthenium (Ru)), the accuracy of the analytical results (though subjected to mathematical corrections) for these analytes may have been affected and should be treated with caution [35].

Type of Sample
Elements in food items analyzed at the Swedish Food Agency (leafy vegetables (2014), seeds, grains, peanuts (2018), and vegetarian protein products (2019)) were determined by using ICP-MS in accordance with the procedures of the NMKL (no. 186 and EN 15763). Colli-sion gas (helium) was used in order to reduce molecular spectral interference. The method includes total microwave acid digestion of the samples using a mixture of concentrated nitric acid and hydrochloric acid (6 + 1 mL). The method is accredited for foodstuffs by SWEDAC in accordance with ISO/IEC 17025. The detection limits are listed in the Supplementary Materials for samples analyzed with this method (wild Ulva, Table S1; pumpkin seeds, sunflower seeds, and peanuts, Table S12; vegetarian protein products, Table S13), along with the expanded measurement uncertainty for each element.

Inorganic Arsenic (iAs) Determination
The determination of iAs in selected food items (algae, bread, gluten-free bread, rice, and rice products) was performed according to the European Standard EN16802 at the Swedish Food Agency. The method is based on extraction with dilute nitric acid and hydrogen peroxide in a hot water bath followed by analysis with strong anion exchange HPLC-ICP-MS. This analytical method was accredited in accordance with ISO/IEC 17025 by the Swedish board for the accreditation and conformity assessment (SWEDAC) of iAs for rice, rice products, and other foodstuffs within the range 1-25,000 µg/kg. The LOD was between 1 and 3 µg/kg, depending on the dilution of the sample prior to analysis. The expanded measurement uncertainty was +/− 19% (coverage factor k = 2) and was estimated based on the reproducibility in collaborative trials within the European Committee for Standardization (CEN), the laboratory's own results in proficiency tests, and from the analysis of certified reference materials (for more details, see Kollander et al., 2019 [36]).

Internal Quality Control
Both laboratories routinely use methods accredited by the Swedish accreditation body, SWEDAC, Borås, Sweden, which require comprehensive documentation and control of quality of all the steps from sample preparation and analyses to reporting results. The accreditation demands yearly participation in proficiency tests in order to control and maintain the quality performance of the laboratories. In addition, the Swedish Food Agency laboratory is appointed by the European Commission (EU) to be the National Reference Laboratory of Sweden for elements and nitrogenous compounds for food and feed and yearly participates in proficiency tests (PTs) arranged by the European Reference Laboratory for metals and nitrogenous compounds (EURL-MN) [5] for total elements and inorganic arsenic.
For quality control at ALS Scandinavia AB, a set of matrix-matched certified reference materials (

Evaluation of Data
The data were evaluated and compiled at the Swedish Food Agency, and a summary of the Cd results is presented in Table 3. For more detailed results of the distribution of all measured elements in the food matrices studied, see Tables S1-S13. A principal component analysis (PCA, Unscrambler 7.5) was performed on standardized data for pasta and rice by Dr. Jean Pettersson from the Department of Chemistry, BMC, Uppsala University, Uppsala, Sweden.

Results and Discussion
The concentrations of elements in traditional and "new" foods are summarized in Tables S1-S13. It should be noted that the concentrations of a few elements in some of the samples have been published previously [16,17,[23][24][25][26][27]37], but the dataset provided in this study covers many more food matrices and has far greater element coverage.
As this study was originally initiated to gain a better overview of Cd concentrations in foodstuffs, the discussion is focused on this element. Levels of some additional elements of EFSA concern (iAs, Ni, and Pb), as well as concentrations of new emerging contaminants (Tl and REE), are touched upon but in a more condensed form. For brevity, only a few examples of possible ways to use this comprehensive dataset are provided.

Cadmium
Levels of Cd in food items contributing 76% of its dietary intake in Sweden, along with food items that are more or less new to the Swedish market, are presented in Table 3. The traditional food with the highest Cd concentration, 0.393 mg/kg, was spinach and the food with the lowest concentration, 0.002 mg/kg, was rice.
Algae products, except for algae oil, were found to have the highest mean concentrations of Cd as well as the highest measured values-over 1 mg/kg. Sunflower seeds were also found to contain substantial levels of Cd, having mean and maximum levels of 0.262 and 0.559 mg/kg, respectively. Table 3. Amount of cadmium (in mg/kg food) present in the three food groups contributing to 76% of the intake of cadmium in Sweden and in some "new" food varieties. For individual concentrations, see Tables S1-S13.   Table S2. ** Note that crisps do not contain as much water as fresh potatoes and therefore contain higher levels of Cd. *** New foods refer to foods that are relatively new to the Swedish market and for which the consumption in Sweden is increasing or is predicted to increase.

Pasta Products
There are no EU MLs for pasta products per se, but there are values for the wheat used in pasta. Generally, dry pasta products, such as those analyzed here, contain solely durum wheat and/or wheat, and levels of Cd can therefore be compared directly with the ML for durum wheat (0.18 mg/kg) or with the ML for wheat germ (0.20 mg Cd/kg) [10]. For cereal-based foods intended for infants and small children, the ML is 0.040 mg Cd/kg, which applies directly to the products as sold. Cadmium levels in pasta grouped according to the main ingredients are presented in Figure 3. The level of tAs are also shown in Figure 3 for information only (not discussed here). The Cd levels vary within the groups, and both low and generally higher levels can be seen in all types of pasta analyzed, as well as in pasta made from "other" ingredients (spelt flour, pea, and soy protein). None of the pasta was labeled as food for infants and young children, and, thus, the ML of 0.040 mg/kg does not apply. However, as pasta is often eaten by children, it is important to note that in 33 of the 104 pasta products studied, the Cd concentration exceeded 0.040 mg/kg. ing to the main ingredients are presented in Figure 3. The level of tAs are also shown in Figure 3 for information only (not discussed here). The Cd levels vary within the groups, and both low and generally higher levels can be seen in all types of pasta analyzed, as well as in pasta made from "other" ingredients (spelt flour, pea, and soy protein). None of the pasta was labeled as food for infants and young children, and, thus, the ML of 0.040 mg/kg does not apply. However, as pasta is often eaten by children, it is important to note that in 33 of the 104 pasta products studied, the Cd concentration exceeded 0.040 mg/kg.  Table S3.
The Swedish pasta analyzed contained about 45-50% Swedish wheat, while the remainder of the wheat was durum wheat produced elsewhere, for example, in Spain or Kazakhstan, and thus the elemental composition also reflects that of the durum wheat produced in other countries. Despite the variable origin of the wheat, it is still possible to distinguish pasta products made from Swedish and Italian wheat by using the PCA performed using concentrations of 18 elements in different pasta products (tAs, Ba, Bi, Cd,  Table S3. The Swedish pasta analyzed contained about 45-50% Swedish wheat, while the remainder of the wheat was durum wheat produced elsewhere, for example, in Spain or Kazakhstan, and thus the elemental composition also reflects that of the durum wheat produced in other countries. Despite the variable origin of the wheat, it is still possible to distinguish pasta products made from Swedish and Italian wheat by using the PCA performed using concentrations of 18 elements in different pasta products (tAs, Ba, Bi, Cd, Cr, Cs, Fe, Hg, Li, Mo, Pb, Sb, Se, Sn, Th, Tl, U, and W levels, presented in Table S3) (Figure 4). The one Swedish-produced pasta grouped with the Italian pastas was produced in Sweden but made from Italian durum wheat. The ability of PCA to distinguish between foods produced at different sites (i.e., determine provenance) using their elemental compositions has previously been reported for durum wheat [38], rice [39], wine [40,41], olive oils [42], and seaweed [43]. The higher Cd levels in Swedish pasta in 2014 were discussed with the producer (2015), and that prompted the use of wheat with lower Cd levels in their products, even though all products had Cd concentrations below the ML of 0.20 mg/kg. Sweden but made from Italian durum wheat. The ability of PCA to distinguish between foods produced at different sites (i.e., determine provenance) using their elemental compositions has previously been reported for durum wheat [38], rice [39], wine [40,41], olive oils [42], and seaweed [43]. The higher Cd levels in Swedish pasta in 2014 were discussed with the producer (2015), and that prompted the use of wheat with lower Cd levels in their products, even though all products had Cd concentrations below the ML of 0.20 mg/kg.  [44]. For detailed information, see Table S3.

Rice and Rice Products
The acceptable Cd concentration is regulated by EU 1881/2006. The maximum levels are 0.15 mg/kg for rice and 0.040 mg/kg in cereal-based foods intended for infants and young children [10]. The Cd level in rice ( Figure 5) is generally lower than in wheat (which is reflected by the lower ML). Since the levels of iAs in rice and rice products are of special concern, data for iAs [23] are included in Figure 5. Only one of the rice products was labeled as a food for infants and young children (rice cakes intended for consumption from eight months of age), and for this product, the corresponding MLs for Cd and iAs were not exceeded. The other rice cakes studied had concentrations exceeding the ML for iAs  [44]. For detailed information, see Table S3.

Rice and Rice Products
The acceptable Cd concentration is regulated by EU 1881/2006. The maximum levels are 0.15 mg/kg for rice and 0.040 mg/kg in cereal-based foods intended for infants and young children [10]. The Cd level in rice ( Figure 5) is generally lower than in wheat (which is reflected by the lower ML). Since the levels of iAs in rice and rice products are of special concern, data for iAs [23] are included in Figure 5. Only one of the rice products was labeled as a food for infants and young children (rice cakes intended for consumption from eight months of age), and for this product, the corresponding MLs for Cd and iAs were not exceeded. The other rice cakes studied had concentrations exceeding the ML for iAs in food intended for infants and young children. In addition, 6 of the 11 rice cakes also had Cd concentrations that exceeded the ML for Cd in cereal-based foods intended for children. Although these rice cakes are not labeled as being intended for infants and young children, rice cakes are a popular snack. Therefore, since 2015, the Swedish Food Agency has advised that rice cakes should not be given to children under the age of six [23,45]. in food intended for infants and young children. In addition, 6 of the 11 rice cakes also had Cd concentrations that exceeded the ML for Cd in cereal-based foods intended for children. Although these rice cakes are not labeled as being intended for infants and young children, rice cakes are a popular snack. Therefore, since 2015, the Swedish Food Agency has advised that rice cakes should not be given to children under the age of six [23,45]. Results for iAs taken from reference [23]. For detailed information about specific products and levels, see Table S4.
The elemental compositions of the different rice products were evaluated via PCA, and the results are presented in Figure 6. In total, the concentrations of 45 elements (Ag, Al, tAs, B, Be, Bi, Ca, Cd, Co, Cr, Cs, Cu, Fe, Hf, Hg, I, K, Li, Mg, Mn, Mo, Nb, Ni, P, Pb, Rb, Re, S, Sb, Sc, Se, Si, Sn, Sr, Ta, Te, Th, Ti, Tl, U, W, V, Y, Zn, Zr) and iAs were included used. Most of the variation can be described by iAs, together with 22 of the elements analyzed (tAs, Ag, Bi, Cd, Co, Cs, Hg, I, K, Li, Mg, Mn, Mo, Ni, P, Rb, Re, S, Sb, Se, Si, Zr). White rice varieties were grouped according to the type of rice and country of origin, while wholegrain rice comprised one group containing a higher amount of minerals, showing that the PCA of elemental composition can be a powerful tool for distinguishing between types of rice and production sites.  [23]. For detailed information about specific products and levels, see Table S4.
The elemental compositions of the different rice products were evaluated via PCA, and the results are presented in Figure 6. In total, the concentrations of 45 elements (Ag, Al, tAs, B, Be, Bi, Ca, Cd, Co, Cr, Cs, Cu, Fe, Hf, Hg, I, K, Li, Mg, Mn, Mo, Nb, Ni, P, Pb, Rb, Re, S, Sb, Sc, Se, Si, Sn, Sr, Ta, Te, Th, Ti, Tl, U, W, V, Y, Zn, Zr) and iAs were included used. Most of the variation can be described by iAs, together with 22 of the elements analyzed (tAs, Ag, Bi, Cd, Co, Cs, Hg, I, K, Li, Mg, Mn, Mo, Ni, P, Rb, Re, S, Sb, Se, Si, Zr). White rice varieties were grouped according to the type of rice and country of origin, while wholegrain rice comprised one group containing a higher amount of minerals, showing that the PCA of elemental composition can be a powerful tool for distinguishing between types of rice and production sites.  Each sample of rice is represented by either the flag of its country of origin, the name of the Continent or if the origin is unknown by "Unknown" (according to the package label). Samples of white rice is grouped according to the type of rice and origin, while the samples of wholegrain rice comprises one group containing a higher number of minerals [46]. For detailed information on levels in respective rice sample, see Table S4.
The levels of the 45 elements analyzed, including iAs, in samples of rice products (rice, noodles, breakfast cereals, rice porridge, rice cakes, and rice drinks, N = 101), including iAs and As, previously reported by the Swedish Food Agency, 2015 [23], can be found in Table S4.  Each sample of rice is represented by either the flag of its country of origin, the name of the Continent or if the origin is unknown by "Unknown" (according to the package label). Samples of white rice is grouped according to the type of rice and origin, while the samples of wholegrain rice comprises one group containing a higher number of minerals [46]. For detailed information on levels in respective rice sample, see Table S4.
The levels of the 45 elements analyzed, including iAs, in samples of rice products (rice, noodles, breakfast cereals, rice porridge, rice cakes, and rice drinks, N = 101), including iAs and As, previously reported by the Swedish Food Agency, 2015 [23], can be found in Table S4.

Bread Products, including Gluten-Free Bread
Samples of bread and gluten-free bread samples were collected within the work of the Swedish Food Composition Database [17] and analyzed for concentrations of vitamins and minerals as composite samples. In this study, the 50 individual bread were separately analyzed for 64 elements (Ag, Al, tAs, Au, B, Ba, Be, Bi, Ca, Cd, Ce, Co, Cr, Cs, Cu, Dy, Er, Eu, Fe, Ga, Gd, Ge, Hf, Hg, Ho, I, K, La, Li, Lu, Mg, Mn, Mo, Na, Nb, Nd, Ni, P, Pb, Pr, Rb, Re, S, Sb, Sc, Se, Si, Sm, Sn, Sr, Ta, Tb, Te, Th, Ti, Tl, Tm, U, W, V, Y, Yb, Zn, Zr) presented in Tables S5 and S6 for bread and gluten-free bread, respectively, including results for iAs in seven products.
The levels of Cd are generally higher in wholegrain wheat breads (fiber-rich white bread) than in breads made from only wheat germ (white bread) (Figure 7 and Table S5). Based on these findings, the Swedish Food Agency conducted a risk assessment study to evaluate whether wholegrain products in general are beneficial for health, despite their higher levels of Cd. Despite the occurrence of elevated Cd concentrations posing a potential risk to the kidneys, the conclusion was that the health benefits associated with the consumption of wholegrain products outweigh the risk [47]. However, other negative health effects associated with the intake of Cd have been reported in the literature. For example, many studies have demonstrated associations between Cd exposure and a decrease in bone density (osteoporosis) (see reviews by Åkesson et al. [48] and Cheng et al. [49]). In general, bread products made from oats or rye, including wholegrain varieties, contain lower levels of Cd. These differences in Cd levels in cereals are reflected in Regulation (EC) No 1881/2006 [10], where the MLs for Cd in oats and rye (0.10 and 0.05 mg/kg, respectively) are below the MLs for durum wheat and wheat.  Relative levels of tAs, Cd, Ni, and Pb in different types of bread, including gluten-free bread products. The highest levels of the elements measured in the bread products were set to 100% in order to compare the occurrence of these heavy metals (including arsenic) in each sort of bread.
The highest values were found for dark gluten-free products and fiber-rich bread. For detailed information, see Table S5 for bread and S6 for gluten-free bread.
Variations in the tAs, Cd, Ni, and Pb concentrations in different sorts of bread are presented in Figure 7. Gluten-free breads, especially dark gluten-free breads, have higher levels of Pb and Ni compared to gluten-containing breads, probably due to the increased amounts of ingredients such as nuts and seeds [50]. The elevated As levels are directly related to the addition of rice flour [51]. As rice (median 0.017 mg Cd/kg) is a common ingredient in gluten-free products, the relatively low level of cadmium compared to that Figure 7. Relative levels of tAs, Cd, Ni, and Pb in different types of bread, including gluten-free bread products. The highest levels of the elements measured in the bread products were set to 100% in order to compare the occurrence of these heavy metals (including arsenic) in each sort of bread. The highest values were found for dark gluten-free products and fiber-rich bread. For detailed information, see Table S5 for bread and S6 for gluten-free bread.
Variations in the tAs, Cd, Ni, and Pb concentrations in different sorts of bread are presented in Figure 7. Gluten-free breads, especially dark gluten-free breads, have higher levels of Pb and Ni compared to gluten-containing breads, probably due to the increased amounts of ingredients such as nuts and seeds [50]. The elevated As levels are directly related to the addition of rice flour [51]. As rice (median 0.017 mg Cd/kg) is a common ingredient in gluten-free products, the relatively low level of cadmium compared to that found in gluten-containing bread products is not surprising. However, there is a need for a more thorough analysis focusing on the presence of bread within the gluten-free cereal product category, especially products with high levels of Cd.

Potatoes and Potato Products
The levels of Al, Cd, and Co were significantly higher in samples of unpeeled compared to peeled potatoes (paired t-test, n = 9, 95% confidence). The relative change in the elemental composition after peeling is presented as the mean for all nine types analyzed ( Figure 8). Here, 100% equals the relative mean element concentration for the potatoes before peeling. A mean of <100% indicates that most of the element was present in the peel, while a mean of >100% reveals that the element was present within the potato and not in the peel. On average, peeling the potatoes reduced the levels by −67, −8, and −12%, for Al, Cd, and Co, respectively ( Figure 8). No significant differences between peeled and unpeeled potato samples were seen for Cr, Cu, Fe, Mn, Ni, Pb, and Zn. Many samples, both peeled and unpeeled, contained Se, Hg, and As levels below the respective LOD, and, thus, the effect of peeling could not be evaluated.  Table S7.
In Table S7, the individual results for all 31 elements analyzed (Al, Ag, As, B, Ba, Be, Ca, Cd, Co Cr, Cu, Fe, Hg, K, Li, Mg, Mn, Mo, Na, Ni, P, Pb, S, Sb, Si, Se, Sr, U, V, and Zn) in 36 potato products, including peeled and unpeeled potatoes, French fries, and crisps, are presented.
Only one sample of sweet potatoes was analyzed, with and without peel. For this single sample, peeling reduced the concentrations of most of the elements, but no general conclusions could be drawn. Note that, even though sweet potatoes (Ipomoea batatas) are often used in the same recipes as potatoes (Solanum tuberosum), they are not a type of "potato." According to the market basket survey conducted in 2015, potatoes and potato products contribute 22% of the dietary Cd intake [16]. Unfortunately, there is no information  Table S7.
In Table S7, the individual results for all 31 elements analyzed (Al, Ag, As, B, Ba, Be, Ca, Cd, Co Cr, Cu, Fe, Hg, K, Li, Mg, Mn, Mo, Na, Ni, P, Pb, S, Sb, Si, Se, Sr, U, V, and Zn) in 36 potato products, including peeled and unpeeled potatoes, French fries, and crisps, are presented.
Only one sample of sweet potatoes was analyzed, with and without peel. For this single sample, peeling reduced the concentrations of most of the elements, but no general conclusions could be drawn. Note that, even though sweet potatoes (Ipomoea batatas) are often used in the same recipes as potatoes (Solanum tuberosum), they are not a type of "potato." According to the market basket survey conducted in 2015, potatoes and potato products contribute 22% of the dietary Cd intake [16]. Unfortunately, there is no information about whether unpeeled products were included in the composite samples analyzed. However, the results from this study show that Cd exposure is typically 8% lower when consuming peeled potato products.

Quinoa and Teff Flour
Quinoa is increasingly being used by restaurants in Sweden as an alternative to potatoes, rice, and pasta. Regarding Cd concentrations, the 10 samples of quinoa analyzed yielded mean and median levels of 0.053 and 0.048 mg/kg, which are similar to the levels reported by Bolaños et al. (2016) [52] but higher than the values obtained for potatoes, rice, and pasta in this study. In Regulation (EC) No 1881/2006 [10], quinoa is grouped with rice and wheat bran, having an ML of 0.15 mg/kg, while Teff belongs to the cereals category, in which the occurrence of Cd is lower, so it has an ML of 0.10 mg/kg. Only two teff samples were analyzed in this study, and the concentrations were in the lower range among the analyzed samples: 0.011 and 0.028 mg Cd/kg, respectively. Lower levels of Cd have been reported in teff flour [51][52][53].
The comparison of the levels of tAs, Cd, Ni, and Pb in quinoa with potatoes, wholegrain pasta (Ni not determined), and rice (wholegrain and parboiled) in this study provides a rough estimate of the differences or similarities regarding these known elements of concern ( Figure 9). For Cd and Pb, the four food items were found to have similar profiles. Levels of tAs were several times higher in rice than in the other three products. The highest level of Ni was seen in quinoa, followed by rice. Ni was not an element of high concern in Europe in 2014 when the pasta was analyzed, and thus, the concentration of this element was not measured. Figure 9. Relative levels of tAs, Cd, Ni (not analyzed in pasta), and Pb in quinoa and products consumed in a similar way in Sweden. For detailed information, see Table S3, S4, S7, and S8.  Tables S3, S4, S7 and S8. For example, Ni levels in pasta and wheat flours can be found in Cubadda et al. (2020) [54] or, for wholegrain wheat and durum wheat, in Swedish Food Agency, 2015 [50]. The minimum and maximum levels of Ni presented are 0.029 and 0.077, and 0.05 and 0.3 mg/kg, respectively.

Seeds
Samples of peanuts, sunflower seeds, and pumpkin seeds were collected within the work of the Swedish Food Composition Database [17] and analyzed for concentrations of vitamins and minerals as composite samples. In this study, the 32 individual samples were separately analyzed for 17 elements (Ag, Al, As, Cd, Co, Cr, Cu, Fe, Hg, Mn, Mo, Ni, Pb, Se, Sn, V, Zn), see Table S12. Sunflower seeds and pumpkin seeds are used in Sweden as common ingredients in bread and other food products. Sunflower seeds are well known to contain Cd at high levels [50,55,56], which is reflected in Regulation (EC) No 1881/2006 [10], where they have a higher ML than other seeds (0.50 mg/kg compared to 0.1-0.3 mg/kg, except for poppy seeds at 1.20 mg/kg). The level of Cd in sunflower seed samples varied from 0.084 to 0.559 mg/kg (median 0.233), while levels were much lower in pumpkin seeds (<0.0018-0.041 mg/kg, median 0.002). The pumpkin seed sample with 0.041 mg/kg, was the only unshelled, roasted, and salted sample, while the rest of the samples were shelled, including the sample with the second-highest concentration of 0.010 mg/kg. The Cd levels were within the same ranges previously reported for sunflower and pumpkin seeds purchased on the Swedish market: 0.29 (0.17) and 0.013 (0.011) mg/kg (mean (median)), respectively [33].
Only five samples of peanuts (all salted, one roasted) were analyzed, so no general conclusion can be drawn from the results, which showed Cd concentrations that varied from 0.012 to 0.153 mg Cd/kg (median 0.030 mg/kg). Despite its name, the peanut belongs to the botanical group of seeds, and its ML is 0.20 mg Cd/kg [10].
Both psyllium and chia seeds are often used as alternatives to similar fiber-rich products containing gluten. In this work, five samples of psyllium seeds were analyzed, and mean and median Cd concentrations of 0.046 and 0.043 mg Cd/kg, respectively, were found. The chia seeds had a lower Cd content with a mean of 0.010 and a median of 0.007 mg/kg. Compared with fiber-rich and gluten-containing alternatives, like wheat bran (around 0.1 mg/kg, [50]), both psyllium and chia seeds contain lower levels of Cd. Rubio et al. (2018) [57] and Bolaños et al. (2016) [52] have reported similar levels of Cd in chia seeds (0.01 ± 0.00 mg/kg (N = 18) and <0.016 (N = 14), respectively) while a broader range, <0.003 to 0.090 mg/kg (N = 9), was reported by Gomez et al. (2021) [58].
The comparison of the tAs, Cd, Ni, and Pb concentrations in the seeds analyzed in this study clearly indicates that sunflower seeds have the highest levels of Cd and Ni ( Figure 10). Both chia and psyllium seeds were shown to contain higher levels of tAs than the other seeds, while elevated levels of Pb were only found in psyllium.
The comparison of the tAs, Cd, Ni, and Pb concentrations in the seeds analyzed in this study clearly indicates that sunflower seeds have the highest levels of Cd and Ni (Figure 10). Both chia and psyllium seeds were shown to contain higher levels of tAs than the other seeds, while elevated levels of Pb were only found in psyllium.  Table S8.
The range of Cd concentrations in rucola was 0.014-0.107 mg Cd/kg, with mean and median values of 0.059 and 0.068 mg Cd/kg, respectively. The ML is 0.20 mg/kg, the same as for spinach, while the ML is 0.10 for other leaf vegetables containing less Cd, for example, iceberg lettuce [10]. For comparison, the Cd levels in spinach and lettuce analyzed within the Swedish sampling program for contaminants are presented in Table 3. Among the spinach samples, the Cd concentration exceeded the ML of 0.20 mg/kg in 3 of the 15 samples analyzed in 2014 and in 1 of 6 samples analyzed in 2015 [24], while all samples of iceberg lettuce (Lactuca sativa) had Cd concentrations below the ML of 0.10 mg/kg.

Vegetarian Protein Products
There are many alternative protein sources to meat available on the market. If traditional meat meals are replaced with other protein sources of plant or marine origin, the elemental composition of the intake will also change. Table S13 presents the analytical results for eight elements of interest (Cd, Co, Cu, Fe, Mn, Mo, Pb, Zn) found in 19 composite samples of meals based on soy, oats, peas, and mycoprotein [37]. The names of the products (escalope, nuggets, balls, mince, and bacon) indicate an intended use as replacements for traditional meat products. For Cd and Pb, the means were 0.014 and 0.005 mg/kg, respectively, which could be compared to the mean values of 0.003 and 0.002 mg/kg found in traditional meat products that an average citizen in Sweden consumes (Food Category Meat MB samples, [16]). Consequently, consuming these protein products instead of meat products will result in a double or higher intake of Cd and Pb. Although based on a rather limited dataset, these results should be taken into consideration when planning of a future studies on this subject. In a study by Furey et al. (2022) [59], all five samples of natural fungi protein had Cd levels < 0.01 mg/kg, while De Marchi et al. (2021) [60] presented quantification of 4 out of 10 samples of plant-based burgers (0.14-0.15 mg/kg, no LOD given). Although the latter study is indeed important and the conclusion that "the heavy metals were not detected" is true, its information is not usable without the LOD. In addition, in view of the low but important differences in concentrations of heavy metals between meat and vegetarian protein replacement products, the analytical method used in these kind of studies should have quantification levels in the ultra-trace (sub-10 −3 mg/kg) range or lower.
3.1.9. Algae General Algae are considered valuable food resources that could be produced more sustainably than other food sources [13]. The increasing interest in algae as a food, and research aimed at optimizing algae production, particularly in the Nordic part of Europe, have drawn attention to the lack of regulations and management tools available to ensure its food safety [11].
Although not yet regarded as traditional food in Sweden, algae are ingredients in certain meals and in food supplements available on the market.

Cadmium in Algae Products Available for Human Consumption
The samples of nori and algae salad had the highest Cd levels measured, with maximum measured concentrations of above 1 mg/kg. Similar levels (1.42 ± 1 mg/kg, N = 8) were seen in Nori in a study by Todorov et al. (2022) [61].
Algae oils were found to have much lower Cd levels than the macroalgae products with mean and median concentrations of 0.008 and 0.004 mg/kg.

Cadmium in Macroalgae-Wild and Farmed
The Cd level in green macroalgae Ulva samples varied from 0.026 to 0.173 mg Cd/kg. The lowest values were found in Ulva fenestrata and the highest were found in Ulva intestinalis. Samples of the latter were collected from the west and east coasts of Sweden, where the salinity varied from 22 at the west coast to 3 g/L at the northern east coast. Similar variations in Cd concentrations within and between Ulva species have also been reported by others [61,62].
Four samples of the brown macroalgae sugar kelp (Saccharina latissima) were analyzed for 72 elements and iAs in this study. The mean and median Cd concentrations were 0.440 and 0.452 mg Cd/kg, respectively. All four samples were farmed in the Koster Archipelago.

Growing Interest about the Elemental Composition of Algae
The information available regarding certain elements in macroalgae farmed in the seas of Northern Europe and intended for food production has increased substantially recently [11,27,[63][64][65][66], as has the interest of the EFSA [12]. Although the focus is not always on the elemental composition per se, awareness of the importance of the elemental composition of algae is growing, considering both toxic elements, such as As, Cd, Ni, Pb, and Hg, and essential ones, such as Cu, Fe, Mo, Se, and iodine (I). Comparing levels of iAs, Cd, Ni, and Pb between the macroalgae analyzed confirms the broad variations in levels, both within and between different species (Figure 11). Cadmium levels in Ulva species were generally lower than in the other species analyzed, while the four samples of Saccharina latissima showed the most uniform distribution of these elements, probably because they were harvested at the same age and from the same area [26,27]. In the comprehensive dataset published by Duinker et al. (2020) [66], the levels of iAs, Cd, and Pb in sugar kelp were 0.03-0.67, 0.16-3.1, and <0.22-5.7 mg/kg, respectively (Ni was not analyzed), which shows the possible variations within the same species. Broad ranges of concentrations of Cd and Pb, within and between different kinds of edible seaweed, have, for example, also been reported by Todorov Table S10 for Saccharina latissma, Table S1 for Ulva, and Table S11 for algae for human consumption.
Iodine is of special concern since some species of macroalgae are known to contain potentially unhealthy high levels of this element [11]. In this work, the level of I in algae ranged from 15 mg/kg in nori to 2500 mg /kg in sugar kelp. An even broader range of 8-10,000 mg/kg was reported for the same species by Duinker et al. (2020) [66].
Due to the large variations between different species of macroalgae, it is of utmost importance to be species-specific when any conclusions are drawn regarding levels of different elements in seaweed.
The concentrations of several elements, including bromine (Br), niobium (Nb), strontium (Sr), titanium (Ti), V, yttrium (Y), and zirconium (Zr) in the macroalgae nori, wakame, "algae salad," and sugar kelp can be 100-fold or even 1000-fold higher than in cereals, potatoes, and vegetables (see Table S11). Consequently, extended consumption of these algae will increase the nutritional intake of these elements with currently "unknown" biological functions.

Other Elements in Traditional and New Food Products
The growing interest in the elemental composition of foods focuses not only on "new" foods but also on "new" less-studied elements. Many elements are finding new uses in modern technology applications, which has resulted in a dramatic increase in their demand and, consequently, also in their global extraction rate. So-called 'technology-critical elements' (TCEs) include most REEs, PGEs, and gallium (Ga), germanium (Ge), In, Nb, tantalum (Ta), tellurium (Te), and Tl. Despite increasing recognition of their prolific release into the environment, their concentration levels in food remain largely unknown.
For example, Tl is an element that might be of concern due to its high toxicity [68,69] with provisional oral reference dose in 10 −5 mg/kg per day [70], and also due to its availability to plants used for food [71]. The highest levels of Tl in this work were found in quinoa (0.031 (0.028) mg/kg), Ulva (0.015 (0.011) mg/kg), sugar kelp (0.0056 (0.0062) mg/kg), and dark gluten-free bread (0.0038 (0.0038) mg/kg). These concentrations can be compared to levels found in the Swedish market basket survey for 2015, where the food categories Figure 11. Relative levels of iAs, Cd, Ni, and Pb in macroalgae. For detailed information and information on additional elements, see Table S10 for Saccharina latissma, Table S1 for Ulva, and Table S11 for algae for human consumption.
Iodine is of special concern since some species of macroalgae are known to contain potentially unhealthy high levels of this element [11]. In this work, the level of I in algae ranged from 15 mg/kg in nori to 2500 mg /kg in sugar kelp. An even broader range of 8-10,000 mg/kg was reported for the same species by Duinker et al. (2020) [66].
Due to the large variations between different species of macroalgae, it is of utmost importance to be species-specific when any conclusions are drawn regarding levels of different elements in seaweed.
The concentrations of several elements, including bromine (Br), niobium (Nb), strontium (Sr), titanium (Ti), V, yttrium (Y), and zirconium (Zr) in the macroalgae nori, wakame, "algae salad," and sugar kelp can be 100-fold or even 1000-fold higher than in cereals, potatoes, and vegetables (see Table S11). Consequently, extended consumption of these algae will increase the nutritional intake of these elements with currently "unknown" biological functions.

Other Elements in Traditional and New Food Products
The growing interest in the elemental composition of foods focuses not only on "new" foods but also on "new" less-studied elements. Many elements are finding new uses in modern technology applications, which has resulted in a dramatic increase in their demand and, consequently, also in their global extraction rate. So-called 'technologycritical elements' (TCEs) include most REEs, PGEs, and gallium (Ga), germanium (Ge), In, Nb, tantalum (Ta), tellurium (Te), and Tl. Despite increasing recognition of their prolific release into the environment, their concentration levels in food remain largely unknown.
For example, Tl is an element that might be of concern due to its high toxicity [68,69] with provisional oral reference dose in 10 −5 mg/kg per day [70], and also due to its availability to plants used for food [71]. The highest levels of Tl in this work were found in quinoa (0.031 (0.028) mg/kg), Ulva (0.015 (0.011) mg/kg), sugar kelp (0.0056 (0.0062) mg/kg), and dark gluten-free bread (0.0038 (0.0038) mg/kg). These concentrations can be compared to levels found in the Swedish market basket survey for 2015, where the food categories Meat and Eggs contained the highest levels of 0.0024 and 0.0025 mg /kg, respectively, while the average values for Vegetables and Cereals were 0.0005 and 0.0008 mg/kg, respectively (Table S2).
The REEs, another group of elements belonging to TCEs, are considered neither essential nor toxic and have unclear biological roles, if any. Potential risks associated with elevated REE exposure are mainly associated with the ability to displace Ca from calciumbinding sites [68]. Although the first papers on REE content in food were already available some 30 years ago (e.g., [72]), reported levels were significantly (by orders of magnitude) higher than in more recent studies [73], which may indicate either a decreasing level of environmental pollution or, more likely, progress in analytical methods for ultra-trace analysis of food matrices. It should be stressed that, in the majority of recent publications, the interest in REE content in various food products mainly stems from either assessment of environmental pollution and/or botanical/geographical origin identification (e.g., [74][75][76][77][78][79][80]).
The majority of food products tested in the present study contain undetectable to very low levels of REEs, demonstrating both their scarcity in the environment and the low bioavailability of these elements. The highest REE concentrations were measured for the food category Sweets. This correlated with Ti concentrations and most likely originated from the use of inorganic/mineral food coloring agents (e.g., titanium dioxide containing REEs as an impurity).

Conclusions
To the best of our knowledge, this study is one of the most comprehensive of its kind, regarding the number of food varieties tested, the element coverage, and availability of data at truly ultra-trace (sub-10 −3 mg/kg) levels. The concentration data acquired can complement information on inorganic constituents in foodstuffs that are currently available on product labels, in various food nutritional tables, on the homepages of brand name holders, and in other relevant surveys. A detailed comparison of our results with previously published data (where available), though potentially intriguing, was outside the scope of this investigation.
Based on the concentration data obtained during this study, it is possible to calculate intakes for both essential and toxic elements, assuming typical consumption scenarios, and such intakes can then be compared with either the recommended daily allowance figures or the accepted toxicity thresholds. In the interest of brevity, we intentionally excluded such topics from the present discussion, although the presented results may aid in the understanding of how ongoing and anticipated changes in the diet of the general population could alter the intake of Cd as well as that of other elements, both essential and toxic. It should be stressed that the selection of food varieties tested is somewhat skewed towards the Swedish market and that concentration levels may change in the future as a result of climate change, nutrient deficiencies in agricultural soils, changes in cultivation practices and animal feed composition, and progress in food processing and packaging, to name but a few factors.
Though interest in inorganic analyses of food products mainly stems from nutritional concerns and the few toxic elements regulated by law, such analyses are increasingly being used in food authentication or provenance studies, as well as in forensics applications, where the availability of reliable information on trace-and ultra-trace-element concentrations is essential.
This study provides levels of elements that are not routinely analyzed in foods and not requested within the EFSA call for data with a focus on the Swedish market. When the general diet is changed, and with the introduction of elements used in modern technology to the food chain, knowledge about the total element composition in various foods is important to provide a long-term perspective on sustainable health practices regarding both traditional and "new" foods.  Table S12. Pumpkin seeds, sunflower seeds, peanuts; Table S13. Vegetarian protein products.